Group Customized Search

ABSTRACT

A computer-implemented method associates a plurality of groups with a user. Each group may have at least one profile. The method also includes receiving a search query from the user and identifying information items associated with the search query. The method computes adjusted scores for the information items based on the groups&#39; profiles, and ranks the information items accordingly before providing the ranked information items to the user. Alternately, a computer-implemented method associates a group having a plurality of profiles with a user. The method also includes receiving a search query from the user and identifying information items associated with the search query. The method computes adjusted scores for the information items based on the group&#39;s profiles, and ranks the information items accordingly before providing the ranked information items to the user.

RELATED APPLICATIONS

This application is a Continuation in Part of U.S. Patent Application Ser. No. 11/394,620, filed Mar. 30, 2006, entitled “Website Flavored Search,” which is hereby incorporated by reference.

This application is related to U.S. patent application Ser. No. 10/890,854, filed Jul. 13, 2004, entitled “Personalization of Placed Content Ordering in Search Results,” which is hereby incorporated by reference.

FIELD OF THE INVENTION

The present invention relates generally to the field of a search engine in a computer network system, in particular to a system and method of customizing rankings of search results in response to search queries submitted by members of one or more user groups.

BACKGROUND OF THE INVENTION

Search engines are powerful tools for locating and retrieving documents from the Internet (or an intranet). Traditionally, the search results produced by a search engine are independent of the user who issued the search query. For example, the search engine generates the same search result for the search query “apple” irrespective of whether the search query is from users interested in Apple® computers or the fruit malus domestica. Clearly the search results returned for the search query “apple” are likely to include some results of little interest to these respective groups of users.

In view of the aforementioned, it would be desirable to have a search engine that can customize its search results so as to highlight information items in the search results that are most likely to be of interest to the users who submit the search queries. Further, it would be desirable for such a system to operate without explicit input from a user with regard to the user's personal preferences and interests, and for the system to protect the privacy interests of its users.

SUMMARY

In some embodiments, a computer-implemented method associates a plurality of groups with a user. Each group may have at least one profile. The method also includes receiving a search query from the user and identifying information items associated with the search query. The method computes adjusted scores for the information items based on the groups' profiles, and ranks the information items accordingly before providing the ranked information items to the user.

In some embodiments, a computer-implemented method associates a group having a plurality of profiles with a user. The method also includes receiving a search query from the user and identifying information items associated with the search query. The method computes adjusted scores for the information items based on the group's profiles, and ranks the information items accordingly before providing the ranked information items to the user.

Some embodiments may be implemented on either the client side or the server side of a client-server network environment.

BRIEF DESCRIPTION OF THE DRAWINGS

The aforementioned features and advantages of the invention as well as additional features and advantages thereof will be more clearly understood hereinafter as a result of a detailed description of preferred embodiments when taken in conjunction with the drawings.

FIG. 1 is a block diagram of an exemplary distributed system that includes a plurality of groups and clients requesting information from an information server in accordance with some embodiments.

FIG. 2 is a flow diagram of a process for generating a group profile using search queries, search results and user activities.

FIG. 3 is a block diagram of a process for updating a group profile by merging an incremental group profile into the group profile.

FIG. 4 is a prophetic example of a curve characterizing the popularity distribution of search queries.

FIG. 5A is a block diagram illustrating how a website group may be associated with multiple profiles in accordance with some embodiments.

FIG. 5B is a block diagram illustrating how an internet address group may be associated with multiple profiles in accordance with some embodiments.

FIG. 5C is a block diagram illustrating how a group may be associated with multiple profiles in accordance with some embodiments.

FIG. 6A is a block diagram of an exemplary category map that may be used for generating category-based group profiles in accordance with some embodiments.

FIG. 6B is a block diagram of an exemplary data structure that may be used for storing category-based group profiles in accordance with some embodiments of the present invention.

FIG. 6C is a block diagram “snapshot” of an exemplary data structure that may be used for storing groups and profiles associated with a user at a particular point in time in accordance with some embodiments.

FIG. 7 is a block diagram of an exemplary data structure that may be used for storing term-based group profiles in accordance with some embodiments.

FIG. 8 is a block diagram of an exemplary data structure that may be used for storing link-based group profiles in accordance with some embodiments.

FIG. 9 is a flow diagram of a process for generating group-dependent search results using group profiles in accordance with some embodiments.

FIG. 10 is a block diagram of exemplary data structures that may be used for storing category-based, term-based, and link-based boost factors for documents in the search results in accordance with some embodiments.

FIG. 11 is a flow diagram of another process for generating group-dependent search results using group profiles in accordance with some embodiments.

FIG. 12 is a block diagram of an exemplary information server in accordance with some embodiments.

FIG. 13 is a flow diagram of a process for providing a user with customized group-dependent search results according to some embodiments.

FIG. 14 is a flow diagram of another process for providing a user with customized group-dependent search results according to some embodiments.

Like reference numerals refer to corresponding parts throughout the several views of the drawings.

DESCRIPTION OF EMBODIMENTS

FIG. 1 is a block diagram of an exemplary environment 100 for implementing some embodiments of the present invention. One or more websites 102 and clients 103 can be connected to a communication network 104. The communication network 104 can be connected to an information server 106. The information server 106 may include a front end server 120, a search engine 122, a document profiler 125, a group profiler 129, a search result ranker 126, a document profile database 123, a content database 124, a search history database 127, and a group profile database 128.

In some embodiments, the information server 106 contains a subset or superset of the elements illustrated in FIG. 1. Although FIG. 1 shows the information server 106 as a number of discrete items, the figure is intended more as a functional description of the various features which may be present in the information server 106 rather than a structural schematic of the various embodiments. In practice, items shown separately could be combined and some items could be further separated, as would be recognized by one of ordinary skill in the art of designing such systems. For example, the four different databases 123, 124, 127, and 128 shown separately in the figure could be implemented by a single database server. The actual number of computers constituting the information server 106 and the allocation of features among the computers will vary from one implementation to another, and may depend in part on the amount of traffic that the information server 106 must handle during peak usage periods as well as during average usage periods.

A website 102 is typically a collection of webpages associated with a domain name on the Internet. Each website (or webpage) has a universal resource locator (URL) that uniquely identifies the location of the website (or webpage) on the Internet. Any visitor can visit the website by entering its URL in a browser window. A website can be hosted by a web server exclusively owned by the owner of the domain name or by an Internet service provider wherein its web server manages multiple websites associated with different domain names. For illustrative purposes, the website 102 includes webpage 116, which may have an associated search box. From the search box, a visitor to the webpage 114 can search the website 102 or the entire Internet for relevant information by entering a search query into the search box. Depending on the context, the term “website” as used in this document refers to a logical location (e.g., an Internet or intranet location) identified by a URL, or it refers to a web server hosting the website represented by the URL. For example, some “websites” are distributed over multiple Internet or network locations, but have a shared web server hosting those locations, and in many situations it is logical to consider those network locations to all be part of “a website.”

A client 103 can be any of a number of devices (e.g., a computer, an internet kiosk, a personal digital assistant, a cell phone, a gaming device, a desktop computer, or a laptop computer) and can include a client application 132, a client assistant 134, and/or client memory 136. The client application 132 can be a software application that permits a user to interact with the client 103 and/or network resources to perform one or more tasks. For example, the client application 132 can be a browser (e.g., the computer program available under the trademark Firefox®) or other type of application that permits a user to search for, browse, and/or use resources (e.g., webpages and web services) at the website 102 from the client 103 and/or accessible via the communication network 104. The client assistant 134 can be a software application that performs one or more tasks related to monitoring or assisting a user's activities with respect to the client application 132 and/or other applications. For instance, the client assistant 134 assists a user at the client 103 with browsing for resources (e.g., files) hosted by the website 102; processes information (e.g., search results) received from the information server 106; and monitors the user's activities on the search results. In some embodiments the client assistant 134 is part of the client application 132, available as a plug-in or extension to the client application 132 (provided, for example, from various online sources), while in other embodiments the client application is a stand-alone program separate from the client application 132. In some embodiments the client assistant 134 is embedded in one or more webpages or other documents downloaded from one or more servers, such as the information server 106. Client memory 136 can store information such as webpages, documents received from the information server 106, system information, and/or information about a user.

The communication network 104 can be any wired or wireless local area network (LAN) and/or wide area network (WAN), such as an intranet, an extranet, or the Internet. It is sufficient that the communication network 104 provide communication capability between the websites 102, the clients 103 and the information server 106. In some embodiments, the communication network 104 uses the HyperText Transport Protocol (HTTP) to transport information using the Transmission Control Protocol/Internet Protocol (TCP/IP). The HTTP permits client computers to access various resources available via the communication network 104. The various embodiments of the invention, however, are not limited to the use of any particular protocol. The term “resource” as used throughout this specification refers to any piece of information or service that is accessible via a URL and can be, for example, a webpage, a document, a database, an image, a computational object, a search engine, or other online information service.

In order to receive group-dependent search results, a user from client 103 (for example) may send to a website 102 a request for a webpage. The website responds by identifying the requested webpage and returning it to the requesting client 103. The webpage may include a document of interest to the user (e.g., a newspaper article). The webpage may also include a search box (e.g., at or near the top of the webpage). While or after browsing the content of the webpage, the user may be interested in getting more information. To do so, the user can enter a search query and submit the search query to the website 102, a search engine, or the like. The search query may include one or more query terms.

As noted above, many websites do not have a dedicated search engine. Their search requests are actually handled by a third-party search engine. In some embodiments, upon receipt of the search query, the website 102 generates and sends a search request to the information server 106. In some other embodiments, the client 103 generates and sends the search request directly to the information server 106 without routing the request through the website 102. In other embodiments, the user may choose to use the website of a third party search engine directly. In any case, the search request may include the search query and unique identifiers of one or more of the following entities: the website 102 being viewed, a website previously viewed by the user, the requesting user, and the requesting client 103. The identifier for a website may be a URL of a particular web page, or a prefix portion of the URL that identifies the website or a portion of the website. The search engine 122 or other portion of the information server 106 may determine the appropriate portion of the URL to use for determining a group associated with the user.

Within the information server 106, the front end server 120 is configured to handle a variety of requests from the websites 102 and the clients 103 via their respective connections with the communication network 104. As shown in FIG. 1, the front end server 120 is connected to the search engine 122 and the search engine 122 is connected to the content database 124, respectively. The content database 124 stores a large number of indexed documents retrieved from different websites. Alternately, or in addition, the content database 124 stores an index of documents stored at various websites. In one embodiment, each indexed document is assigned a page rank according to the document's link structure. The page rank serves as a query-independent measure of the document's importance.

The front end server 120 passes the search request onto the search engine 122. The search engine 122 then communicates with the content database 124 to select a plurality of information items (e.g., documents) in response to the search request. The search engine 122 assigns a generic ranking score to each information item based on the item's page rank, the text associated with the item, and the search query. For ease of discussion, information items will often be referred to as “documents;” but it is to be understood that information items need not be documents, and may include other types or forms of information.

The search engine 122 is also connected to the document profile database 123. The document profile database 123 may store a document profile for each indexed document in the content database 124. Both the document profile database 123 and the content database 124 are connected to the document profiler 125. For each document in the content database 124, the document profiler generates a document profile by analyzing the content of the document and its link structure. The generation of document profiles is independent of the operation of the search engine 122. In some embodiments, the document profiler 125 is invoked to generate a document profile whenever the information server 106 identifies a new document or a new version of an existing document on the Internet. In other embodiments, the document profiler 125 is invoked periodically to generate document profiles for all new files identified during a predetermined time period. In some embodiments, instead of being two separate entities, the document profile database 123 and the content database 124 are merged together so that a document and its associated profile can be located by a single database query.

There is a connection from the search engine 122 to the search result ranker 126. Through this connection, the search engine 122 sends the identified documents and their associated document profiles to the search result ranker 126. The search result ranker 126 has a connection to the group profile database 128. Like the document profile database 123, the group profile database 128 stores a large number of group profiles including group profiles of one or more groups associated with a requesting user. For example, the search result ranker 126 may use a group profile associated with users of a website 102 (e.g., a website currently or recently visited by the user) to convert the generic ranking score of each identified document into a group-dependent ranking score. The documents are then re-ordered in accordance with their respective group-dependent ranking scores. Next, the search result ranker 126 creates a search result in accordance with the updated order of the documents. The search result includes multiple document links, at least one for each document. The search result, or a portion of the search result (e.g., information identifying the top 10, 15 or 20 information items or documents), is returned to the requesting client 103 and displayed to the user through the client application 132. The user, after browsing the search result, may click one or more document links in the search result to download and view one or more documents identified by the search result.

While the above description divided tasks among the search engine 122, search result ranker 126 and front end server 120 in a particular way, this particular division of tasks is exemplary, and other divisions may be used in other embodiments. For instance, the group profile (associated with the user from whom a search query is received) may be transmitted with the search query to the search engine 122, and the search engine 122 may use that information to compute group specific document scores for ranking the search results. In effect, this would merge the search result ranker 126 into the search engine 122. Alternately, an identifier of the group profile may be transmitted with the search query to the search engine 122. If the search engine 122 has a copy of the group profile or has access to the group profile, it can then use that information to compute group specific document scores. In yet other embodiments, other divisions of tasks may be used.

An important aspect of the process of serving group-dependent search results is the generation and maintenance of the group profiles stored in the group profile database 128. A group profile should reflect the interests of the users of the associated group, and in many embodiments the group profile will be unique to its associated group. For example, users of a consumer electronics website should have a group profile that boosts webpages related to electronic products while users of an on-line grocery store should have a group profile that promotes webpages related to food. Users of both the consumer electronics website and the on-line grocery store may be associated with both groups.

In most embodiments, a group profile is not static, because a static group profile is unlikely to result in the information server 106 serving the most relevant search results to users of the associated group. Instead, a group profile is updated from time to time, (i.e., periodically) so as to re-align the group profile with the current interest of the users associated with the group. While some group profiles may remain virtually static for long periods of time (e.g., for groups associated with a small, static population of users, and/or users having interests focused on a very narrow range of topics), many group profiles will vary over time as the associated users change and as the users' interests vary over time. In an exemplary embodiment, a respective group profile may be based on dated information, with older information receiving lower weightings than newer information when constructing a vector or other representation of the group profile. For example, the information for each successively older time period may be down weighted by a predefined scaling factor, so that information from a period that is more than N (e.g., a value between 5 and 20) periods old has less than half the impact on the group profile as information from the current period.

In some embodiments, the profile for a particular group may include weights depending on the number of “clicks” or visits by the users to a particular website, webpage, or set of websites during a particular window in time. For example, if users associated with a particular location group (e.g., Alexandria, Va.) frequently visit the website of a local park (e.g. Mason Neck State Park), the weight for the local park website within the local group profile would be increased. In some embodiments, the weights in a group profile may be associated with one or more half-lives or other time modulations to allow the information server to provide the most relevant and timely search results. For example, “clicks” on the Mason Neck State Park website may be more frequent on Fridays and Saturdays in the months of April through October than at other times, so the weight for the Mason Neck Park website for users associated with the Alexandria, Va. group might be higher for a search done on a Friday in July than for a search done on a Tuesday in December. In another example, users associated with a consumer electronics group may “click” on information about Shakira at a particularly high frequency at a particular time, but the frequency of “clicks” may decay over a year, a week, a day, a minute, or other time period. In some embodiments, the time decay rate of “clicks” is stored in the form of half lives over several different periods of time. A group profile can also be based on characteristics other than user clicks. Other characteristics of user behavior that can be used in a group profile include one or more of the following: the length of time that a user interacts with the website, the proportion of the website viewed by the user, actions (in addition to clicks) taken by a user while visiting the website (e.g., printing, bookmarking, cutting and pasting, annotating), and a user's activity subsequent to the interaction with the website.

There are similarities between a group profile and a user profile, as described above. Both profiles can be used to finely tune the search results generated by the search engine. Both need information about at least one user's search history in order to capture the user's dynamic search interest. But there are also significant differences between the two types of profiles. A typical user profile is generated by analyzing an individual user's search history. This user profile is only used to modulate search results responsive to search queries submitted by the same user. For the same search query, two different users may receive different search results from the same search engine if they have different user profiles. In contrast, a group profile is usually generated by analyzing the search history of multiple users so as to characterize the multiple users' interests. The size of a group may range, for example from a predefined minimum value to approximately one million, or as many as the number of users for whom characteristics may be reasonably stored. The minimum size of a group may be selected or determined so as to preserve the privacy interests of the group members. A group profile can be used to modulate search results responsive to search queries submitted by any user from the same group, including new users of the group who made no prior “contribution” to the group profile. Therefore, the same user submitting the same search query from two different locations (e.g. websites, computers, ip addresses, or geolocations) may receive different search results if the two locations have different group profiles.

The group profile also has an important advantage over the user profile in terms of protecting a user's privacy. Thus, in some embodiments, a group profile is based on information associated with at least a sufficient number of users to protect the privacy of those users. In some embodiments a group profile contains at least approximately 256 users to protect individual users' privacy, while in other embodiments the minimum size of a respective group is a value between ten and 512, while in another embodiment the minimum size is between ten and 10,000). A user profile is associated with an individual user. To create the user profile, the individual user, either explicitly or implicitly (e.g., by monitoring or logging search queries and other online activities of the user), needs to complete a survey of his or her personal preferences. This survey indicates what information items may be of interest to the user. Further, the user must have an account at a website or a search engine system and the user must log into his or her account to invoke the user profile to personalize the search results. In contrast, the creation and usage of the group profile does not require any personal information from any user. A group profile is associated with a group of users, not an individual user. Any individual user's activity is attributed to all the users in the corresponding group or groups. A user does not need to log into his or her account at the website in order to use the group profile. As long as the user may be associated with a group, the information server automatically “personalizes” the corresponding search result in accordance with the group profile.

As shown in FIG. 1, the group profiler 129 is responsible for generating and updating group profiles. In order to capture the current user interest associated with a particular group, the group profiler 129 may need to have access to the users' search history. The users' search history includes the search queries submitted by users, the search results responsive to the search queries, the users' activities on the search results (e.g., selection of a document link, sometimes called “clicking” on a search result, amount of time spent at a document after selecting the document link, mouse hovering time over a document link, or the like), the current website viewed by the user, the last n websites viewed by the user (where n is a whole number, typically on the order of five to ten), the user's favorite websites, or the like.

In some embodiments, when the front end server 120 receives a search, it submits a copy of the search query to the search engine 122 in order to solicit a search result. In addition, the front end server 120 sends another copy of the search query to the search history database 127. The search history database 127 then generates a record, the record including at least the search query and one or more group identifiers or other information from which one or more group identifiers can be derived.

The search result ranker 126 prepares search results responsive to the search query. The search result (i.e., information representing at least a portion of the search results) is sent back to the requesting client through the front end server 120. A copy of the search result, or a portion of the search result, is also stored in the search history database 127 together with the search query record. The client assistant 134 at the requesting client monitors the requesting user's activities on the search result, e.g., recording the user's selection(s) of the document links in the search result and/or the mouse hovering time on different document links. In some embodiments, the client assistant 134 or the group profiler 129 determines the document “dwell time” for a document selected by the user, by determining the amount of time between user selection of the corresponding document link and the user exiting from the document. In some embodiments, the client assistant 134 includes executable instructions, stored in the webpage(s) containing the search result, for monitoring the user's actions with respect to the search results and transmitting information about the monitored user actions back to the information server 106. In some embodiments, the search results are served to the requesting users with an embedded client assistant 134 that sends information about the user activities on the search results to the group profiler 127. The information server 106, in turn, stores information about these user activities in the search history database 127 for subsequent use. The search history database 127 may allocate amounts of storage space for different groups. As a result, the volume of search history associated with a group does not exhaust its designated space or waste too much space before the next scheduled profile updating.

For example, the group profiler 129 records the moment that a user submits a search query (t0), the moment that the user clicks the first document link in the corresponding search result (t1), and the moment that the user clicks the second document link in the search result (t2), etc. The differences between two consecutive moments (e.g., t1−t0 or t2−t1) are reasonable approximations of the amount of time spent viewing the search result or the document whose link was selected by the user. In some embodiments the group profiler 129 has no information about the user's dwell time for the last document in the search result that the user selects for viewing. In some other embodiments (e.g., where at least some users “opt in” to a version of the client assistant that collects additional information about the users' online activities), the group profiler 129 also receives click and timestamp information for user actions after the user finishes viewing documents from a search result. Continuing the above example, the group profiler 129 further records the moment that the user submits a second query (t3), the moment the user selects a document from the second search results (t4), and so on. Furthermore, the group profiler 129 may record the moment (t5) when the user either closes the browser window that was being used to view search results and documents listed in the search results or navigates away from the webpage or document with the search results. This additional information enables the group profiler 129 to determine the user dwell time for all search result documents (i.e., documents listed in search results) viewed by a user, which in turn enables the group profiler 129 to generate a more accurate group profile for a group.

Based on characteristics associated with one or more users, the group profiler 129 generates a group profile. FIG. 2 is a flow diagram of a process for generating a group profile using characteristics associated with the user in accordance with some embodiments of the present invention. Initially, the group profiler 129 identifies characteristics associated with the user (210). The group profiler 129 may identify a website; a location (including a geolocation) such as a country, region, city or the like; an internet address (e.g. the Internet Protocol (ip) address, TCP/IP address, Ethernet address, network address, subnet address, or the like); a domain name or a portion of a domain name; a host name; users' history (including past viewed websites, past search queries, selected search results, dwell time or the like); user profiles or portions thereof, a language; and/or other characteristics that may be associated with more than one user (such as a user type, for example a power user or a teenager). Some groups associated with a user may be determined based on known affiliations of the user, such as membership in a mailing list, membership of a website, clubs, teams, businesses, schools, etc. At least some of these groups may be groups that the user has explicitly or implicitly joined. These user characteristics may include some or all search queries submitted by users. In some cases, the identified search queries may comprise a subset or sampling of the submitted search queries. Search queries submitted during a predetermined time period presumably represent the general interest of the users submitting the queries. The search queries may capture dynamic user interests that vary by time.

The group profiler 129 may identify online activities of users. Identified user activities may include user clicks on document links in search results. In another example, identified user activities may include mouse hovering time on the document links. Generally speaking, a user clicks a document link if the user is interested in the document's content. Similarly, the fact that the mouse moves onto a particular document link and stays there for a substantial amount of time indicates that this document is relevant to the user's interest. In some embodiments, information about the mouse hovering time may be unavailable.

From the user activities on different search results, the group profiler 129 can identify documents selected by the users. In some embodiments, the group profiler 129 visits the content database 124 to retrieve the profiles of the corresponding documents. As noted above, each identified document may have a profile (e.g., a document profile) that was previously generated. If any of the identified documents do not yet have profiles, those documents can be ignored, or the group profiler may call upon the document profiler 125 to produce document profiles for those documents.

In these ways, the group profiler 129 may also identify other users having one or more of the same characteristics (215). User characteristics may be correlated by topic, time or the like to form groups. The group profiler 129 then associates the user with other users having the same characteristics in at least one group (220). One or more group profiles are then generated (230). The group profiler 129 may generate a group profile based on the user characteristics, the retrieved document profiles, or the like. Some of the group profiles may be website profiles, the generation and use of which are described in patent application Ser. No. 11/394,620. A group profile may be validated, for example, by comparing the group to an average of other groups of the same type, by averaging the differences between groups, or other validation procedures. The group profile may include one or more of the following: a weighted listing or vector of categories (sometimes called a category-profile), key terms from search queries and/or user visited documents (sometimes called a term profile), and information about links to user visited documents (sometimes called a link profile). The group profile is stored in the group profile database 128. The search result ranker 126 can retrieve the group profile to re-order the ranks of the documents within a search result.

In some other embodiments, operation 230 may include a clustering operation in which user characteristics are clustered using statistical analysis to determine suitable groupings. The clustering may be based on, for example, the fact that a user clicks a link. Alternatively, the group profiler may directly match a document's URL against a known set of URLs associated with a particular category. In either case, the group profiler 129 does not need to access the documents' contents in order to generate the group profile.

In yet other embodiments, operation 230 may be augmented by a process that maps the user characteristics to a set of categories. For example, the categorization of queries can be based on the terms in the queries themselves, or by accessing the profiles of the top N search results (e.g., the top 5, 10, 15 or 20 search results) produced by those queries, merging those document profiles to produce a query profile for each query, and merging the query profiles, weighted in accordance with their frequency of submission to generate a group profile. As discussed below with reference to FIG. 4, this process may exclude queries that are deemed to be unlikely to be related to the primary interests of the users.

As noted above, a group profile may be updated from time to time in order to keep track of the current interests of the users associated with the group. In some embodiments, a group profile is updated at a predetermined time interval (e.g., every week or every day). In some other embodiments, a group profile is updated whenever the number of new search queries by members of the group reaches a threshold value since a last (i.e., most recent) update. Whenever it is time to update the group profile, the group profiler 129 repeats the aforementioned process to update the group profile.

In some embodiments, different groups generate substantially different magnitudes of traffic and therefore should be treated differently in terms of profile updating. For instance, a group associated with a popular domain name may generate heavy traffic, on the order of tens of thousands of clicks per day while a smaller group may have a much lower click rate.

Some groups may generate so much traffic that the group definition should be refined. For example, a group based on grouping the users' ip addresses in a range could include users of a proxy, which would be unlikely to have any correlation with user's interests. In such a case, the outlier ip address (the suspected proxy ip address in this example) could be excluded from the group. There are two additional issues with significant traffic during a short time period. First, the group's profile may be biased by this traffic peak. Special care may be required to make sure that the group profile has an appropriate balance between the short-term and long-term interests of the users, such as by excluding or down-weighting the associated elements of the group profile. Second, the search history database 127 may not have the space to store all the search history. One approach to solve this issue is to intentionally ignore some of the search queries, search results and user activities. This may be accomplished by sampling the search queries, search results and/or user activities so as to produce an unbiased sample of the search history. While the extent of the sampling may vary from one embodiment to another, experiments suggest that a search history encompassing several months of user activities will have sufficient data to generate a reliable group profile, for most groups, so long as (A) the sampling is done in a manner that avoids significant biases, and (B) it includes user activity data corresponding to a few weeks of representative search history.

Alternatively, the space shortage issue can be solved by generating a series of incremental group profiles for different portions of the search history and merging the incremental group profiles into the group profile. As shown, for example, in FIG. 3, the group profiler 129 first generates an incremental profile 311 for the search history section 301. Each search history section 301, 303, 305 may include a predefined quantity of search history information, or it may include search history information for a predefined length of time (e.g., an hour), or it may include a portion of the search history selected in accordance with predefined selection criteria. The process of generating an incremental group profile is similar to the process discussed above in connection with FIG. 2. The incremental profile 311 is equivalent to the search history section 301 in terms of characterizing the interests of the users. Once the incremental profile 311 has been created, the corresponding search history section 301 in the database can be overwritten by new entries entering the database. Similarly, the search history section 303 can be overwritten after the incremental profile 313 is generated. After the creation of the incremental profile 315, the group profiler 129 can create the new group profile 337 by merging the incremental profiles 311, 313, and 315 into the old group profile 331. In sum, the group profiler 129 is able to take into account the entire search history by creating incremental group profiles for search history sections 301, 303, and 305 and by merging an existing group profile with incremental profiles 311, 313, and 315.

A group profile may be used for anonymously “personalizing” search results responsive to search queries submitted by a user associated with a group. An underlying assumption in the present specification is that a user's search queries are, more or less, related to at least one of the groups associated with the user. If not carefully filtered out, the search history associated with popular, but irrelevant, terms may seriously “contaminate” the group profile and twist the search results in an unexpected direction. Another source of contamination of the group profile is query terms that have very low popularity. Special treatment may be necessary to make sure that user activities with respect to very low popularity query terms do not significantly bias the search results.

In some embodiments the group profiler 129 (FIG. 1) identifies search queries, and potentially other user behavior or user information, that differentiate the group from the general population of online users, and then either filters the received information or weights it so as to emphasize characteristics of the group that are distinct from characteristics of the general population of online users. FIG. 4 is an exemplary curve 400 characterizing the popularity distribution of search queries submitted by members of a group. All the search queries are divided into three categories by the two thresholds 415 and 425. The leftmost category 410 includes those search queries that are “abnormally” popular, but may be less relevant to the specific interests of the group. The search query “Britney Spears” being submitted by a user associated with a Northern California group is an example of a search query in this category. The group profiler 129 may eliminate or reduce the influence of the search history associated with these queries on the group profile by giving them relatively low weights. The middle category 420 includes those search queries that are reasonably popular and relevant to the group. The search history corresponding to these search queries may be granted higher weights to make a major contribution to the group profile. Finally, the rightmost category 430 includes those queries that are only made occasionally or by a single user associated with the group. They may be treated in a manner similar to the queries in the leftmost category 410.

There are multiple factors determining the contribution of a search query (or a corresponding search result) in the middle category 420 to the group profile. For example, the popularity of the search query and the amount of user activities on the search result affect the contribution of the search query and the search result on the group profile. Time is another important factor. In some embodiments, recent search history plays a more prominent role than less recent search history in the formation of the group profile. One skilled in the art can easily apply similar principles to other aspects of the search history associated with the group.

FIGS. 5A-5C are block diagrams illustrating various types of groups, including group i, group j, and group k, having multiple profiles produced by one or more group profilers 129. A particular user may be associated with these groups, or a subset or superset thereof.

FIG. 5A is a block diagram illustrating how website_i group 530 may be associated with multiple profiles in accordance with some embodiments. A user may be associated with one or more website groups. For example, i may be any whole number and a user may be associated with a website_(—)1 group and a website_(—)2 group. The profiles 531, 533, 535, and 537 are produced by one or more group profilers 129, based on the online behavior (sometimes called the online history) of the users in the group. Online behavior of the group includes the search history of users associated with the website_i. The search history involves different types of information from different sources, such as search queries 501 submitted by users associated with website_i, search results 503 generated by the search engine in response to the search queries from users associated with website_i, and activities 505 of users associated with website_i on the search results.

In some embodiments, group profile generation is divided into multiple sub-processes. Each sub-process produces a specific type of group profile characterizing the interests of the website users from a particular perspective. Four examples of the types of group profiles that may be produced by sub-processes of the group profiler 129 (FIG. 1) are:

-   -   a category-based group profile 531—this type of profile may be         generated by correlating the search history of a set of users         with a set of categories, which may be organized in a hierarchal         fashion, where each category may be given a weight indicating         the relevance of the category to the interests of users;     -   a term-based group profile 533—this type of profile is generated         by abstracting the search history for a set of users with a         plurality of terms, wherein each term may be given a weight         indicating the relevance of the term to the interests of the         users;     -   a link-based group profile 535—this type of profile is generated         by identifying a plurality of links that are directly or         indirectly related to the search history, where each link may be         given a weight indicating the relevance of the link to the         interests of the users; and     -   a cluster-based group profile 537—this type of profile is         generated by clustering, or performing statistical analysis of         the search history for a set of users, where each cluster may be         given a weight indicating the relevance of the cluster to the         interests of the users.

In some embodiments, the website_i group 530 may have only a subset of the group profiles 531, 533, 535, and 537. For example, the website_i group 530 may include a single term-based group profile 533. In some embodiments, the group 530 includes a plurality of group profiles. In some embodiments, at least one of plurality of group profiles is a combination of two or more of the aforementioned group profiles 531, 533, 535, and 537. In some other embodiments, the category-based, term-based and/or link-based group profiles are further processed to generate a cluster-based group profile. In yet other embodiments, the cluster-based group profile appears in the form of multiple cluster-based sub-profiles characterizing different aspects of the group. In other embodiments, the cluster based group profile 537 is generated independently of the category-based, term-based, and link-based group profiles using statistical methods.

The category-based group profile 531 may be constructed, for instance, by mapping search history items (e.g., search queries, content terms, and/or user-selected documents) to categories, and then aggregating the resulting sets of the categories and weighting the categories. The categories may be weighted based on their frequency of occurrence in the search history items. In addition, the categories may be weighted based on the relevance of the search history items to the categories. The search history items accumulated over a period of time may be treated as a group for mapping into weighted categories. Other suitable ways of mapping the search history into weighted categories may also be used. In addition, category-based group profiles may also be based on, or take into account, information about the language(s) used by the websites visited by a group of users, the reading level of such websites, and other characteristics of the websites that may be used for re-scoring search engine search results.

FIG. 5B is a block diagram illustrating how an ip address type group may be associated with multiple profiles in accordance with some embodiments. In other embodiments, each of these profiles may be associated with a separate group, based on the online behavior of the group. Online group behavior includes the search history of users associated with the ip address range _j, where j may be any whole number. The ip address range _j, may be, for example, the set of Internet Protocol addresses having the same first 24 bits or having the last 8 bits fall into a predetermined range. The search history involves different types of information from different sources, such as the search queries 506 submitted by users associated with ip address range _j, the search results 507 generated by the search engine in response to the search queries from users associated with ip address range _j, and the activities 508 of users associated with ip address range _j on the search results. The ip address range _j group may have one or more of the following types of group profiles: a category-based group profile 541, a term-based group profile 543, a link-based group profile 545, and a cluster-based group profile 547 as described above with respect to the website_i group 530. A user may be associated with one or more groups, including one or more ip address range groups. For example, a user may be associated with website_(—)1 group, ip address range_(—)2 group, and ip address range_(—)3 group or a subset or superset thereof.

FIG. 5C is a block diagram illustrating how any type of group_k 550 may be associated with multiple group profiles in accordance with some embodiments. The group profiles are created based on online behavior of the group. Online behavior of the group includes the search history of users associated with the group_k. The search history involves different types of information from different sources, such as the search queries 511 submitted by users associated with group_k, the search results 513 generated by the search engine in response to the search queries from users associated with group_k, and the activities 515 of users associated with group_k on the search results. The group_k group may have one or more of the following types of group profiles: a category-based group profile 551, a term-based group profile 553, a link-based group profile 555, and a cluster-based group profile 557 as described above with respect to the website_i group 530. A user may be associated with one or more groups, since k may indicate any whole number. For example, a user may be associated with website_(—)1 group, ip address range_(—)2 group, and group 3 or a subset or superset thereof.

FIG. 6A illustrates a hierarchal category map 600 according to the Open Directory Project (http://dmoz.org/). Starting from the root level of map 600, documents are organized under several major topics, such as “Art”, “News”, “Sports”, etc. These major topics are often too broad to delineate the specific interest of a user. They are further divided into multiple more specific sub-topics. For example, the topic “Art” may comprise the sub-topics like “Movie”, “Music”, and “Literature” and the sub-topic “Music” may further comprise sub-sub-topics like “Lyrics”, “News”, and “Reviews.” Note that each topic (or sub-topic) is associated with a unique category identifier like 1.1 for “Art”, 1.4.2.3 for “Talk Show”, and 1.6.1 for “Basketball.”

The categories shown in FIG. 6A are only for illustrative purposes. One skilled in the art will appreciate that there are many other ways of categorizing documents. For example, different concepts can be extracted from the contents of the documents and different categories of relevant information are grouped in accordance with these concepts. The interests of users associated with a particular group may be associated with multiple categories at different levels, each having a weight indicative of the category's relevance to the group users' interest. The categories and their associated weights can be determined from analyzing the online behaviors of users associated with the group.

FIG. 6B is a block diagram of an exemplary data structure, a category-based group profile table 650, which may be used for storing category-based group profiles in accordance with some embodiments of the present invention. The category-based group profile table 650 includes a table 640 having a plurality of records 642, each record including a GROUP_ID, a PROFILE_ID and a pointer pointing to another data structure, such as table 660-1. A group may have one or more profiles to better serve different user groups. For example, the group “GROUP_(—)1” has at least two different profiles, “PROFILE_(—)1” and “PROFILE_(—)2.” These two different profiles may, for example, correspond to search histories aggregated over different time periods. In other words, the introduction of different profiles for a group refines the interests of the group users. This is particularly useful for a large group associated with a broad spectrum of users. Table 660-1 includes two columns, CATEGORY_ID and WEIGHT. The CATEGORY_ID column contains a category's identifier, for example as shown in FIG. 6A, and the value in the WEIGHT column indicates the relevance of the category to the interests of the users.

Different profiles for the same time period can be generated in different ways, to reflect different aspects of the users in the group (e.g., short term, medium term, or long term interests). This may be accomplished by putting different emphasis or different weighting on different portions of the data used to generate the group profiles. Some group profiles may be generated for special time periods, such as holidays and events (e.g., Christmas, Olympics, etc.) during which the behavior of users may change significantly. The data for such special time periods may also be removed, or down-weighted, when generating “regular” profiles for a group of users.

In some embodiments, the search history items are automatically classified in different clusters. Clusters may be more dynamic than categories, since categories are typically pre-generated. Search history items associated with different groups are classified against the same set of categories. In contrast, there may not be a predefined set of clusters for a particular group. The search history may fall into a dynamically generated set of clusters. Therefore, clusters may be better tailored to characterize the interests and preferences of the group's users or provide additional information about a group to improve the customization of search results. For convenience, many of the discussions of profiles in this document use categories as an example. But it will be clear to one skilled in the art that the underlying algorithms are also applicable to clusters with no or little adjustment.

A category-based group profile, based upon the category map 600, is a topic-oriented implementation of a group profile. The items in a category-based profile can also be organized in other ways. In one embodiment, the interests of the website users can be categorized based on the formats of the documents identified by the website users, such as HTML, plain text, PDF, Microsoft Word, etc. Different formats may have different weights. In another embodiment, the interests of the website users can be categorized according to the types of the identified documents, e.g., an organization's homepage, a person's homepage, a research paper, or a news group posting, each type having an associated weight. Documents can also be categorized by document origin, for instance the country associated with each document's host. In yet another embodiment, two or more of the above-identified category-based profiles may co-exist, with each one reflecting a respective aspect of the interests of the website users.

FIG. 6C is a block diagram “snapshot” of an exemplary data structure which may be used for storing groups and profiles associated with a user in accordance with some embodiments. Since the groups associated with the user may change over time and group profiles are dynamically changing, the snapshot 670 will change accordingly. The snapshot 670 includes a plurality of group tables 672, one for each group associated with the user. For example, in the user associated with snapshot 670 is associated with K groups, so the snapshot 670 includes group table 672-1 for records associated with group 1 (website i), group table 672-2 for records associated with group 2 (ip address range), and group table 672-K for records associated with group K (location).

Each group table 672 may store a group confidence value record 674 for the group, indicating the weight (also called the confidence value) of the group in the re-ranking process. In some embodiments, all groups begin with a default weight or group confidence value of one. Then modifications may be made to the group confidence value to reflect the appropriate weight of the group as associated with the user. For example, if a user is loosely associated with a group, the group confidence value may be lowered. Similarly, if a group is incoherent or has a low coherence, the group confidence value may be lowered. (Here coherence is used in the technical sense to refer to the degree to which members of a group are similar to other members of the group and dissimilar to members of other groups.) Group confidence values may also vary by group type. For example, location type groups may generally have higher (or perhaps, lower) confidence values than website type groups. Group confidence values may also vary by any other factor that affects the preferred weight of a group in computing the adjusted score for documents in the search result, including by query type (i.e., varying the group confidence value when computing the adjusted scored in response to an image query as opposed to map query, etc.). For example, a high traffic internet address group may reflect the users' proxy server, which is unlikely to have any significant relationship to users' interests and should therefore have a low confidence value relative to groups that more consistently reflect their users' interests. In some cases, when the group confidence value approaches or reaches zero, the user is no longer associated with the group.

Each group table 672 may also include profile confidence value records for every group profile of each group, for example 676-1 and 676-2 for Group 1, 676-3 and 676-4 for Group 2, and 676-2X-1 and 676-2X for Group X. Each profile confidence value record 676 may include a profile confidence value (e.g., Profile 1 Conf. Value) indicating the weight of each profile as associated with the group in the re-ranking process for a particular user; a unique identification (ID) of the profile associated with each group (e.g. Grp1-Prf1 ID); and a pointer to a group profile table, such as category-based group profile table 650, term-based group profile table 700, link-based group profile table 800, or the like. In some embodiments, all profiles begin with a default profile confidence value of one. Then modifications may be made to the profile confidence value to reflect the appropriate weight of the profile as associated with the user and the group as described with respect to the group confidence value above. For example, group 1, based on website i, may have a short term profile, profile 1, and a long term profile, profile 2. The profile confidence value for the short term profile 1 may be raised for a news query when website i is www.cnn.com based on the assumption that current news is more interesting to users associated with www.cnn.com. In some cases, when the profile confidence value approaches or reaches zero, the profile is no longer associated with the user or the group.

In some embodiments, an information server stores information identifying a limited number of groups per user. In addition, one or more groups may be associated with a user on the fly, for instance based on the user's IP address or the website from which the user is submitting a search query. Any groups not associated with a user are implicitly assigned a default confidence value of zero. In some embodiments, group memberships (i.e., groups associated with a user) are updated from time to time based on “recent history” (new data concerning recent online behavior of the user). This may include increasing the confidence of groups for which there is evidence of continued membership, decreasing the confidence of groups for which there is a lack of evidence of continued membership or evidence of decreased activity. A group may be removed from the set of groups associated with a user when the confidence value of the group falls below a predefined threshold value (e.g., 0.2 or any other appropriate value). Furthermore, since some group membership information may be determined on the fly, confidence values for those groups may be based on other information, such as a website's coherence value (see definition of coherence value, above).

FIG. 7 is a block diagram of an exemplary data structure, a term-based group profile table 700, which may be used for storing term-based group profiles in accordance with some embodiments of the present invention. The table 700 includes a plurality of records 710, each record corresponding to a group's term-based profile. A term-based group profile record 710 includes a plurality of columns including a GROUP_ID column 720 and multiple columns of (such as TERM, WEIGHT) pairs 740. The GROUP_ID column stores a group identifier. Each (TERM, WEIGHT) pair 740 includes a term of typically one to three words that is deemed relevant to the interests of the users and a weight associated with the term indicating the relevance of the term. The weight of a term is not necessarily a positive value. A negative weight suggests that the website users disfavor documents including this term in the search results.

Besides term-based and category-based profiles, another type of group profile is referred to as a link-based profile. As discussed above, the page rank of a document is based on the link structure that connects the document to other documents on the Internet. A document having more links pointing to it is often assigned a higher page rank and is therefore deemed more popular by the search engine. Link information of documents selected by users can be used to infer the interests of the users. In one embodiment, a list of preferred URLs is identified for users by analyzing the click rate of these URLs. Each preferred URL may be further weighted according to the mouse hovering time by the users at the URL. In another embodiment, a list of preferred web hosts is identified for the users by analyzing the users' visit rate at different web hosts. When two or more preferred URLs are related to the same web host, the weights of the two or more URLs may be combined as the weight of the web host.

FIG. 8 is a block diagram of an exemplary data structure that may be used for storing link-based group profiles in accordance with some embodiments of the present invention. The link-based profile table 800 includes a table 810 that includes a plurality of records 820, each record including a GROUP_ID and a pointer pointing to another data structure, such as table 810-1. Table 810-1 may include two columns, LINK_ID 830 and WEIGHT 840. The LINK_ID 830 may be associated with a preferred URL or host. The actual URL/host may be stored in the table instead of the LINK_ID, however it is preferable to store the LINK_ID to save storage space.

A preferred list of URLs and/or hosts includes URLs and/or hosts that have been directly identified by the users. The preferred list of URLs and/or host may further extend to URLs and/or hosts indirectly identified by using methods such as collaborative filtering or bibliometric analysis, which are known to one of ordinary skill in the art. In one embodiment, the indirectly identified URLs and/or hosts include URLs or hosts that have links to/from the directly identified URLs and/or hosts. These indirectly identified URLs and/or hosts are weighted by the distance between them and the directly identified URLs or hosts. For example, when a directly identified URL or host has a weight of 1, URLs or hosts that are one link away may have a weight of 0.5, URLs or hosts that are two links away may have a weight of 0.25, etc. This procedure can be further refined by reducing the weight of links that are not related to the topic of the original URL or host, e.g., links to copyright pages or web browser software that can be used to view the documents associated with the user-selected URL or host. Irrelevant Links can be identified based on their context or their distribution. For example, copyright links often use specific terms (e.g., “copyright” and “All rights reserved” are commonly used terms in the anchor text of a copyright link); and links to a website from many unrelated websites may suggest that this website is not topically related (e.g., links to the Internet Explorer® website are often included in unrelated websites). The indirect links can also be classified according to a set of topics or categories and links with very different topics or categories may be excluded or be assigned a low weight.

The types of group profiles discussed above are generally complementary to one another since different profiles characterize the interests of users from different vantage points. However, this does not mean that one type of group profile, e.g., the category-based profile, is incapable of playing a role that is typically played by another type of group profile. By way of example, a preferred URL or host in a link-based profile is often associated with a specific topic, e.g., finance.yahoo.com is a URL focusing on financial news. Therefore, what is achieved by a link-based profile that comprises a list of preferred URLs or hosts may also be achievable, at least in part, by a category-based profile that has a set of categories that cover the same topics covered by preferred URLs or hosts.

FIG. 9 is a flow diagram of a process for generating group-dependent search results using the various types of group profiles in accordance with some embodiments of the present invention. Initially, the search engine 122 receives a search query submitted by a user (910). In response, the search engine 122 may optionally generate a query strategy (915). For example, the search query is normalized so as to be in proper form for further processing, and/or the search query may be modified in accordance with predefined criteria so as to automatically broaden or narrow the scope of the search query. Next, the search engine 122 searches the content database 124 for documents that match the search query (or the query strategy, if one is generated). The search engine 122 identifies a set of documents that match the search query (920), each document having a generic ranking score that depends on the document's page rank and the search query. All three operations (910, 915 and 920) are typically conducted by the search engine 122. The net result is an initial set of search results.

Each group associated with the requesting user is identified (922). In some embodiments, some or all of the requesting user's group identifier(s) are embedded in the search query by the client assistant 134 or other means. Based on the group identifier(s), the search result ranker 126 identifies the associated group profiles in the group profile database 128 (925). For each document identified by the search engine 122 the search result ranker identifies a document profile (930), based on which a generic ranking score is derived.

Next, the search result ranker 126 analyzes each identified document to determine one or more boost factors using the group and document profiles (935) and then assigns the document a group-dependent ranking score using the document's generic ranking score and the boost factors (940). The search result ranker 126 iterates the process for every identified document (942). The search result ranker 126 re-orders the list of documents according to their group-dependent ranking scores (945) to produce re-ordered search results. At least a portion of the re-ordered search results (e.g., the top N ranked items, based on the re-ordering), including links to a list of documents, are sent to the requesting client 103.

In some embodiments, the analysis of an identified document at 935 includes determining a correlation between the document's content and the group profiles. Furthermore, in some embodiments, this operation includes accessing a previously computed document profile for the document and then determining a correlation between the document profile and the group profiles. In some embodiments, determining the correlation includes one or more operations that are “dot product” computations, which determine the extent of overlap, if any, between the document profile and the group profiles. In addition, instead of determining and then applying a boost factor (as in operations 935 and 940), some documents may have their group-dependent ranking score set very high or very low in accordance with information in a group profile. For instance, for a group associated with “Apple computers,” documents from websites associated with fruit and produce may be assigned a predefined very low group-dependent ranking score.

FIG. 10 is a block diagram of exemplary data structures that may be used for storing category-based, term-based, and link-based boost factors for documents in the search results in accordance with some embodiments of the present invention. For each candidate document, each identified by a respective DOC_ID, category-based document information table 1010 includes a plurality of identified categories and associated weights, term-based document information table 1030 includes multiple pairs of relevant terms and associated weights, and link-based document information table 1050 includes a set of links and corresponding weights.

The rightmost column of each of the three tables (1010, 1030 and 1050) stores the boost factor (i.e., a computed score) of a document when the document is evaluated using one specific type of group profile. A document's boost factor can be determined by combining the weights of the items associated with the document. For instance, a category-based or term-based boost factor for users associated with an ip address range group may be computed as follows. The users may favor documents related to science with a weight of 0.6, and disfavor documents related to business with a weight of −0.2. Thus, when a science document matches a search query, it will be boosted over a business document. In general, the document topic classification may not be exclusive. A candidate document may be classified as being a science document with probability of 0.8 and a business document with probability of 0.4. A link-based boost factor may be computed based on the relative weights allocated to the preferred URLs or hosts in the link-based profile. In one embodiment, the term-based profile rank can be determined using known techniques, such as “term frequency-inverse document frequency” (TF-IDF). The “term frequency” of a term is a function of the number of times the term appears in a document. The “inverse document frequency” of a term is an inverse function of the number of documents in which the term appears within a collection of documents. For example, very common terms like “word” occur in many documents and consequently are assigned a relatively low inverse document frequency, while less common terms like “photograph” and “microprocessor” are each assigned a relatively high inverse document frequency.

In some embodiments, when a search engine generates a search result in response to a search query, a candidate document D that satisfies the search query is assigned a query score, QueryScore, in accordance with the search query. This query score is then modulated by document D's page rank, PageRank, to generate a generic ranking score, GenericScore, that is expressed as GenericScore=QueryScore*PageRank.

This generic ranking score may not appropriately reflect document D's relevance to a particular group of users if the users' interest is measurably different from that of a random user of the search engine. The relevance of document D to the users can be characterized by a set of boost factors, based on the correlation between document D's content and the group's term-based profile, herein called the TermBoostFactor, the correlation between one or more categories associated with document D and the group's category-based profile, herein called the CategoryBoostFactor, and the correlation between the URL and/or host of document D and the group's link-based profile, herein called the LinkBoostFactor. Therefore, document D may be assigned a group-dependent ranking score that is a function of both the document's generic ranking score and the various group profile-based boost factors. In one embodiment, this group-dependent ranking score can be expressed as: GroupScore=GenericScore*(TermBoostFactor*CategoryBoostFactor*LinkBoostFactor), where a BoostFactor of 1.0 does not modify the generic score, and a value above or below 1.0 reduces or increases the generic score, respectively. The relative importance of each type of profile or boost factor is implemented by controlling the range of values that are allowed for a given type of boost factor. For example, a boost factor having a range of 0.1 to 10 has more importance in determining the GroupScore than a boost factor having a range of 0.5 to 2.0.

In other implementations, a linear combination of boost factors is used: GroupScore=GenericScore*(Wterm*TermBoostFactor+Wcategory*CategoryBoostFactor+Wlink*LinkBoostFactor) or GroupScore=GenericScore*f(Wterm*TermBoostFactor+Wcategory*CategoryBoostFactor+Wlink*LinkBoostFactor), where the weights (Wterm, Wcategory, Wlink) are assigned so that the value in parentheses in the above equations is equal to about 1.0 if the document is to be neither promoted nor demoted in rank for the group, above 1.0 if the document should be promoted, and below 1.0 if the document should be demoted. The greater the deviation from 1.0, the stronger the promotion or demotion of the document. The function f( ) in the last of the equations shown above can be a non-linear function (e.g., f(x)=x^(n) where n is any suitable real value) that emphasizes or de-emphasizes the deviation from 1.0 of the value in the parentheses. In some embodiments the function f( ) is a transform function used to normalize the linear combination of boost factors to a range that is suitable for a combined boost factor. For example, the argument (input value) of the function f( ) may range from −1 to 1 (or any other suitable input range), while the value produced by the function f( ) ranges from 0.2 to 2.0 (or any other suitable output range). The f( ) portion of the above equation (i.e., the value produced by applying the function) corresponds to BoostFactor in the equation in the following paragraph.

In another embodiment, in which the group has a single profile, the group-dependent ranking score can be expressed as: GroupScore=GenericScore*BoostFactor where the “BoostFactor” is based on the correlation between document D's content and the group's profile.

FIG. 11 is a flow diagram of another process for generating group-dependent search results using group profiles in accordance with some embodiments of the present invention. Initially, the search result ranker 126 receives a search query submitted by a user associated with at least one group (1110). In response, the search result ranker 126 may optionally generate a generic query strategy (1115). The search result ranker 126 identifies the group profiles associated with the user's group(s) in the group profile database 128 (1125). Unlike the embodiment discussed above in connection with FIG. 9, the generic query strategy may be modulated by the group's profile to create a group-dependent query strategy (1165). For example, relevant terms from the group profile may be added to the search query with associated weights. In various embodiments, the group-dependent query strategy is created by the search engine 122, the front end server 120, or the search result ranker 126, respectively. In some other embodiments, a copy of the group profile(s) is generated by the group profiler 129 and the group-dependent query strategy is created by the website 102 from which the user is submitting the search query. Next, the search engine 122 searches the content database 124 (optionally using the group-dependent query strategy) for documents matching the query (1170). The documents are then ordered according to their group-dependent ranking scores (1175). When using the group-dependent query strategy, the documents identified by the content database 124 may be implicitly ordered by their associated query-dependent ranking score.

FIG. 13 is a flow diagram of a process for providing a user with customized group-dependent search results using group profiles according to some embodiments. After receiving a search query from the user (1300), a database search is performed to identify information items associated with the search query (1330). In addition, the process identifies a plurality of groups associated with the user (131 0). For example, a user might be associated with an internet address group based on the inclusion of the ip address of the user's computer in an ip address range associated with the internet address group and a location group based on the geolocation of the user's computer as inferred from the computer's ip address. At least one profile for each group is looked up or accessed (1320). For example, the search result ranker 126 may access the group profile database 128 to access each group's profile. These two steps (1310, 1320) may be done before or after the process identifies information items associated with the search query (1330).

Once search results have been identified, the relevance of each information item to the user is determined based on the groups associated with the user. For example, the search result ranker 126 computes an adjusted score or group score for each document based on the document profile and the groups' profiles (1340). The adjusted score for each document k is a function of the GenericScore (as defined above), GroupProfiles(i, j), GroupConfs(i), ProfileConfs(j), and DocumentProfile(k) for all groups i and profiles j where i, j, and k are whole numbers. For example, group profiles GroupProfiles(i, j) as depicted in FIG. 6C include the profiles for groups 1 through X, such as Grp1-Prf1, Grp2-Prf2, etc. Thus, in FIG. 6C there are X groups each having two profiles for a total of 2X profiles. GroupConfs(i) are the group confidence values stored in records 674-1 through X, while ProfileConfs(j) are the profile confidence values stored in records 676-1 through 676-2X. The DocumentProfile(k) is the profile of each document k and may include indications of the document's content and/or the corresponding document profile stored in document profile database 123. In some embodiments the adjusted score for each document k may be expressed as: AdjustedScore(k)=DocumentProfile(k)*[GenericScore*Σ_(i)GroupConfs(i)*Σ_(j)[ProfileConfs(j)*GroupProfiles(i, j)]] where Σ_(i) indicates summation over all i groups and Σ_(j) indicates summation over all j profiles.

Once the adjusted score for each information item in the search result is computed, the information items are ranked accordingly (1350), and then information identifying at least a portion of the ranked search results (e.g., the top N ranked items, where N is a suitable integer) is provided to the user (1360). For example, the search engine and search ranker may produce over one thousand ranked search results, but the user may be sent a smaller number of top ranked results, where the number is between ten and 260, or between ten and 130.

FIG. 14 is a flow diagram of a process for providing a user with customized group-dependent search results using group profiles according to some embodiments. After receiving a search query from the user (1300), a database search is performed to identify information items associated with the search query (1330). In addition, the process identifies a group associated with the user (1410). For example, a user might be associated with an internet address group based on the inclusion of the ip address of the user's computer in an ip address range associated with the internet address group. A plurality of profiles for the group are looked up or accessed (1420). For example, the search result ranker 126 may access the group profile database 128 to access the group's long term and short term profiles. These two steps (1410, 1420) may be done before or after the process identifies information items associated with the search query (1330). Then an adjusted score is computed based on the group's profiles (1430). The computation of the adjusted score may be done in a manner explained above. Once the adjusted score for each information item in the search result is computed, the information items are ranked accordingly (1350), and information identifying at least a portion of the ranked search results (e.g., the top N ranked items, where N is a suitable integer) is provided to the user (1360).

Referring to FIG. 12, an exemplary information server 1200 typically includes one or more processing units (CPU's) 1202, one or more network or other communications interfaces 1210, memory 1212, and one or more communication buses 1014 for interconnecting these components. The communication buses 1014 may include circuitry (sometimes called a chipset) that interconnects and controls communications between system components. The system 1200 may optionally include a user interface, for instance a display and a keyboard. Memory 1212 may include high speed random access memory and may also include non-volatile memory, such as one or more magnetic disk storage devices. Memory 1212 may include mass storage that is remotely located from the CPU's 1202. In some embodiments, memory 1212 stores the following programs, modules and data structures, or a subset or superset thereof:

-   -   an operating system 1216 that includes procedures for handling         various basic system services and for performing hardware         dependent tasks;     -   a network communication module 1218 that is used for connecting         the information server 1200 to other servers or computers via         one or more communication networks (wired or wireless), such as         the Internet, other wide area networks, local area networks,         metropolitan area networks, and so on;     -   a system initialization module 1220 that initializes other         modules and data structures stored in memory 1212 required for         the appropriate operation of the information server 1200;     -   a search engine 122 for processing a search query, identifying         and ordering a search result according to the search query;     -   a content database 124 for storing a plurality of indexed         document retrieved from the Internet;     -   a group profiler 129 for processing data presenting the online         behavior of one or more groups of users and creating and         updating one or more profiles that characterize the interests of         the users associated with the one or more groups;     -   a search history database 127 for storing search histories         associated with different groups including search queries,         search results and user activities;     -   a group profile database 123 for storing group profiles         associated with different groups;     -   a document profiler 125 for analyzing a document's content and         context and creating a profile for the document;     -   a document profile database 123 for storing document profiles         associated with different documents stored in the content         database 124; and     -   a search result ranker 126 for generating a group-dependent         ranking score for each document identified by the search engine         122 using a group profile and re-ordering the documents in a         search result in accordance with their group-dependent ranking         scores.

In some embodiments, the information server 106 may not have access to all the search history associated with a website. For example, there may be an agreement between a website 102 and the information server 106 with respect to the search queries submitted from the website 102. According to the agreement, when a user visiting the website 1027 submits a search query to the information server 106, the information server 106 is required to send the corresponding search result to the website 102 rather than the requesting user at a client 103. The website 102 may modify the search result, e.g., attaching advertisements or other information to the search result, and then serves the modified search result to the requesting user at the client 103.

In this scenario, the information server 106 may have no information identifying the requesting user and the client 103, and may also be unable to monitor the user's activities on the search result. For example, the information server 106 may not receive any information identifying the document links in the search result that have been clicked by the user. Similarly, the information server 106 may not receive any information identifying the document links over which the user moves his or her mouse link and the corresponding mouse hovering time. In other words, the information server 106 has very limited or no exposure to the activities of the website users on the search results. Therefore, the information server 106 has to rely on the user activities on search results from other venues to generate the group profile.

In some embodiments, by examining the search queries submitted from different websites, the information server 106 may identify another website similar to the website in question. Two websites are deemed similar if a predefined number or percentage of search queries submitted from the two websites is identical. It is also reasonable to infer that users of the two similar websites may have similar interests and therefore the user activities associated with one website are a reasonable proxy of the user activities associated with the other one. If the information server 106 can access the user activities associated with one of the two websites (e.g., there is no agreement to deliver the search results to the website), the information server 106 can use the same user activities to create the group profile for the other website.

When there is no other website similar to the website in question, the information server 106 may utilize monitored user activities associated with search queries submitted directly to the search engine (e.g., search queries submitted using a toolbar search box or a webpage associated with the information server 106) as the proxy of a particular website. For instance, the search query “golf courses in mountain view” may be submitted both to a golf-focused website, and to a general purpose search engine. Profile information developed from clicks on the search results of this search query is used to generate a group profile by combining or aggregating statistical information related to the queries received from each respective website.

Placed content may be displayed to users of search services, email services, and a variety of other services provided via the Internet or other wide area networks. For example, when search results are returned to a user in response to a search query, often times certain placed content is returned as well. Placed content is usually in the form of advertising, but could be any type of content related to the search query or to a document being sent to the user. Generally, placed is be any type of content where content providers compete or pay for placement. The techniques discussed above for selecting and ranking information items can also be used for selecting and/or ranking placed content to be presented to users. In particular, in some embodiments, group profiles are used to select advertisements or other placed content to be presented to users along with search results. For example, different advertisements may have different sets of key terms. A correlation of the key terms of each advertisement in a set of advertisements with a term-based group profile (or a category-based profile, or both) associated with a group of users produces a booster factor for the advertisement. This boost factor may be used to promote or demote the particular advertisement in response to a search query submitted by a user associated with the group. For example, when the information server 106 receives a search query “world cup 2006” from a member of a group that is positively weighted in the soccer category, it may promote those advertisements covering soccer gear, ticket sale for the 2006 FIFA World Cup Germany, and hotel reservations at the German cities hosting the soccer game, etc.

The foregoing description, for purpose of explanation, has been described with reference to specific embodiments. However, the illustrative discussions above are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Many modifications and variations are possible in view of the above teachings. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best utilize the invention and various embodiments with various modifications as are suited to the particular use contemplated. 

1. A computer-implemented method, comprising: associating a plurality of groups with a user; accessing at least one profile for each of the plurality of groups associated with the user; receiving a search query from the user; identifying a plurality of information items associated with the search query; computing an adjusted score based on the profiles of the groups; ranking the information items in accordance with the adjusted score; and providing the ranked information items to the user.
 2. The computer-implemented method of claim 1, further comprising: identifying a website associated with the user; determining a website profile of the website; determining a determined group in accordance with the website profile; associating the determined group with the user.
 3. The computer-implemented method of claim 1, further comprising: assigning profile confidence values to at least one respective profile of at least one respective group of the groups; and computing the adjusted score in accordance with the profile confidence value.
 4. The computer-implemented method of claim 3, wherein assigning the profile confidence value further comprises assigning the profile confidence value in accordance with a query type of the search query.
 5. The computer-implemented method of claim 1, further comprising: assigning group confidence values to respective groups of the plurality of the groups; and computing the adjusted score in accordance with the assigned group confidence values.
 6. The computer-implemented method of claim 5, wherein assigning the group confidence value further comprises: evaluating a coherence of a respective group of the plurality of groups; evaluating a type of the respective group; and assigning the group confidence value in accordance with the coherence and the type of the respective group.
 7. The computer-implemented method of claim 6, wherein evaluating the type of the respective group further comprises: if the respective group associated with the user is an internet address type group, determining a traffic volume of an internet address or internet address range associated with the user; and assigning the group confidence value in accordance with the traffic volume.
 8. The computer-implemented method of claim 1, wherein associating the plurality of groups with the user further comprises: identifying an internet address of the user; determining if the internet address is associated with an internet address group; and associating the internet address group with the user in accordance with the internet address of the user.
 9. The computer-implemented method of claim 8, wherein determining if the internet address is associated with the internet address group further comprises: evaluating a coherence of the internet address group; evaluating a number of other users associated with the internet address group; and if the coherence is greater than a predetermined coherence and the number is greater than a predetermined value determining that the internet address is associated with the internet address group.
 10. The computer-implemented method of claim 1, wherein associating the plurality of groups with the user further comprises: identifying a location of the user; determining if the location is associated with a location group; and associating the location group with the user in accordance with the location of the user.
 11. The computer-implemented method of claim 1, wherein associating the plurality of groups with the user further comprises: identifying a history of the user; determining if the history is associated with a respective group; and associating the respective group with the user in accordance with the history of the user.
 12. The computer-implemented method of claim 11, wherein identifying the history of the user further comprises identifying at least one of a website visited by the user, a query submitted by the user, and user interaction by the user with search results associated with the query.
 13. The computer-implemented method of claim 1, wherein associating the plurality of groups with the user further comprises identifying a respective group corresponding to a user profile of the user.
 14. The computer-implemented method of claim 1, wherein associating the plurality of groups with the user further comprises: identifying a domain name associated with the user; determining if domain name is associated with a domain name group; and associating the domain name group with the user in accordance with the domain name associated with the user.
 15. The computer-implemented method of claim 1, wherein computing an adjusted score based on the profiles of the groups further comprises: assigning a profile confidence value to each profile of the groups; assigning a group confidence value to each of the plurality of the groups; calculating the adjusted score based on the profile confidence value of each profile of the groups and the group confidence value of each of the plurality of the groups.
 16. A computer system for managing time and place information, comprising: memory; one or more processors; one or more programs stored in the memory and configured for execution by the one or more processors, the one or more programs including: instructions for associating a plurality of groups with a user; instructions for accessing at least one profile for each of the plurality of groups associated with the user; instructions for receiving a search query from the user; instructions for identifying a plurality of information items associated with the search query; instructions for computing an adjusted score based on the profiles of the groups; instructions for ranking the information items in accordance with the adjusted score; and instructions for providing the ranked information items to the user.
 17. A computer program product for use in conjunction with a computer system, the computer program product comprising a computer readable storage medium and a computer program mechanism embedded therein, the computer program mechanism comprising: instructions for associating a plurality of groups with a user; instructions for accessing at least one profile for each of the plurality of groups associated with the user; instructions for receiving a search query from the user; instructions for identifying a plurality of information items associated with the search query; instructions for computing an adjusted score based on the profiles of the groups; instructions for ranking the information items in accordance with the adjusted score; and instructions for providing the ranked information items to the user.
 18. A computer-implemented method, comprising: associating a first group having a plurality of profiles with a user; receiving a search query from the user; identifying a plurality of information items associated with the search query; computing an adjusted score based, at least in part, on the profiles of the first group; ranking the information items in accordance with the adjusted score; and providing the ranked information items to the user.
 19. The computer-implemented method of claim 18, further comprising: identifying a website associated with the user; determining a website profile of the website; determining a group in accordance with the website profile; associating the group with the user.
 20. The computer-implemented method of claim 18, further comprising: assigning profile confidence values to at least one respective profile of the plurality of profiles; and computing the adjusted score in accordance with the profile confidence values.
 21. The computer-implemented method of claim 20, wherein assigning the profile confidence values further comprises assigning the profile confidence values in accordance with a query type of the search query.
 22. The computer-implemented method of claim 18, further comprising: assigning a respective group confidence value to a respective group and computing the adjusted score in accordance with the respective group confidence value.
 23. The computer-implemented method of claim 22, wherein assigning the group confidence value further comprises: evaluating a coherence of the respective group; evaluating a type of the respective group; and assigning the group confidence value in accordance with the coherence and the type of the respective group.
 24. The computer-implemented method of claim 23, wherein evaluating the type of a respective group further comprises: if the respective group associated with the user is an internet address type group, determining a traffic volume of an internet address or internet address range associated with the user; and assigning the group confidence value in accordance with the traffic volume.
 25. The computer-implemented method of claim 18, further comprising: identifying an internet address of the user; determining if the internet address is associated with an internet address group; and associating the internet address group with the user in accordance with the internet address of the user.
 26. The computer-implemented method of claim 25, wherein determining if the internet address is associated with the internet address group further comprises: evaluating a coherence of the internet address group; evaluating a number of other users associated with the internet address group; and if the coherence is greater than a predetermined coherence and the number is greater than a predetermined value determining that the internet address is associated with the internet address group.
 27. The computer-implemented method of claim 18, further comprising: identifying a location of the user; determining if the location is associated with a location group; and associating the location group with the user in accordance with the location of the user.
 28. The computer-implemented method of claim 18, further comprising: identifying a history of the user; determining if the history is associated with a respective group; and associating the respective group with the user in accordance with the history of the user.
 29. The computer-implemented method of claim 28, wherein identifying the history of the user further comprises identifying at least one of a website visited by the user, a search query submitted by the user, and user interaction by the user with search results associated with the search query.
 30. The computer-implemented method of claim 18, further comprises identifying a group corresponding to a user profile of the user.
 31. The computer-implemented method of claim 18, further comprising: identifying a domain name associated with the user; determining if domain name is associated with a domain name group; and associating the domain name group with the user in accordance with the domain name associated with the user.
 32. The computer-implemented method of claim 18, wherein computing an adjusted score based, at least in part, on the profiles of the first group further comprises: assigning a profile confidence value to each profile; assigning a group confidence value to respective groups including the first group; calculating the adjusted score based on the profile confidence value of each profile and the group confidence value of each of the respective groups.
 33. A computer system for managing time and place information, comprising: memory; one or more processors; one or more programs stored in the memory and configured for execution by the one or more processors, the one or more programs including: instructions for associating a first group having a plurality of profiles with a user; instructions for receiving a search query from the user; instructions for identifying a plurality of information items associated with the search query; instructions for computing an adjusted score based on the profiles of the first group; instructions for ranking the information items in accordance with the adjusted score; and instructions for providing the ranked information items to the user.
 34. A computer program product for use in conjunction with a computer system, the computer program product comprising a computer readable storage medium and a computer program mechanism embedded therein, the computer program mechanism comprising: instructions for associating a first group having a plurality of profiles with a user; instructions for receiving a search query from the user; instructions for identifying a plurality of information items associated with the search query; instructions for computing an adjusted score based on the profiles of the first group; instructions for ranking the information items in accordance with the adjusted score; and instructions for providing the ranked information items to the user. 